160 likes | 352 Views
Heat Transfer in a Liquid-Solid Circulating Fluidized Bed Reactor with Low Surface Tension Media. Name : Dongsheng Guo Major : Fermentation. Content. Introduction Experiment Results and Discussion. Introduction. Employed in diverse fields.
E N D
Heat Transfer in a Liquid-Solid Circulating Fluidized Bed Reactor with Low Surface Tension Media Name :DongshengGuo Major : Fermentation
Content • Introduction • Experiment • Results and Discussion
Introduction • Employed in diverse fields. The temperature fluctuations in those heterogeneous processes are highly complicated and irregular. The heat transfer characteristics in liquid-solid circulating fluidized beds have been studied with limited kinds of liquid.
Introduction Actually, it has been frequently encountered that the surface tension of continuous liquid media has been relatively low comparing with that of water or aqueous solutions. In the present study, the heat transfer characteristics of liquid-solid circulating fluidized beds with relatively low surface tension media were investigated.
Experiment The glass beads was used as solid phase, and mixtures of tap water with ethyl alcohol were used as a continuous liquid phase. The diameter of solid particles was either 0.5, 1.0, 2.0 or 3.0 mm and density ware 2500 kg·m−3. The surface tension of continuous liquid phase was in the range of (55.73-72.75)× 10−3N·m−1.
Experiment 1、Effects of surface tension of liquid phase on theεs. • 6、Effects of surface tension of liquid phase on the heat • transfer coefficient. 2、Typical example of ΔT fluctuations. 3、Effects of liquid velocity on the heat transfer coefficient. 4、Effects of particle size on the heat transfer coefficient. 5、Effects of solid circulation rate on the heat transfer coefficient.
Effects of solid circulation rate on the heat transfer coefficient
Effects of surface tension of liquid phase on the heat transfer coefficient
Results • The experimentally obtained values of heat • transfer coefficient were correlated in term of • operating variables such as liquid velocity, • solid circulation rate, particle size and surface • tension of liquid phase by means of non-linear • regression method. The correlation is which is fitted with the experimental h with acorrelation coefficient of 0.954. Eq. (4) is valid in the following ranges of operating variables: 0.205≤ UL ≤0.300 m·s−1, 2.5≤ Gs ≤8.0 kg·m−2·s−1, 0.5≤dP ≤3.0×10−3m and 55.73≤ σL ≤72.75×10−3N·m−1.